View clinical trials related to Open-Angle Glaucoma.
Filter by:Anaesthetic procedures in ophthalmology surgery have been a subject rapidly evolving in the past decades. When deciding for a retrobulbar block, the local injection of varying mixtures and volumes of fast-acting anesthetics (such as lidocaine) - with or without a vasoconstrictive agent (such as adrenaline) - coupled with Hyaluronidase have been the standard care to provide painless surgery while minimizing the possible risks such as increased intraocular pressure (IOP), brainstem anesthesia, toxic reaction and ocular blood flow changes. These iatrogenic-induced vascular dysfunctions have been also suggested to play a role in intra-operatory vision loss (a "wipe-out" phenomenon) in patients with advanced glaucoma. The rationale for the use of epinephrine in retrobulbar anesthesia is to slow absorption of the anesthetic in general circulation and thus to achieve a longer effect in the orbit. However, studies on ocular blood flow after adrenaline-containing compounds have consistently showed a decrease in ocular blood flow, thus raising the issue of whether it should be used in patients with known vascular dysfunction, namely glaucoma patients. Nevertheless, there has been no study to verify this claim concerning the safety of non-adrenaline containing anesthetics. Injecting a pre-determined volume of anesthetic compound behind the globe, regardless of its formulation has also been debated. The orbital pressure increase can lead to a number of adverse reactions, not only increasing IOP but also potentially decreasing vascular input by local compression. In glaucoma for instance, there has been suggested optic nerve sheaths to be less elastic than in healthy individuals, potentially making this structure less compliant to outside compression. These more rigid orbital tissues could also impair the orbit's ability to deal with the iatrogenic increased volume. As seen, the current concepts on the impact of ocular anesthesiology in the orbit and the vascular supply to the eye are limited to a small number of non-homogeneous studies. We aim to study this impact through a non-invasive, widely established ultrasound based method of ocular blood flow research (color Doppler Imaging). Potentially, our study could help determine a taylor-made choice of the anesthesiology procedure to apply to a specific patient, thereby advancing the current standard of care in ophthalmology.
Glaucoma is a leading cause of blindness worldwide, whose treatment - intraocular pressure lowering - is only partially effective in preventing disease progression. Accordingly, other variables, such as ocular blood flow-related factors, have been implicated in disease pathogenesis. However, most findings involving vascular variables come from partial, small-scale studies. Furthermore, recent technological advances have identified a number of ocular blood flow variables that have yet to be tested in large scale trials. Therefore, a study that specifically aims at uncovering the role of vascular aspects in glaucoma is needed. For this purpose, a cross-sectional, observational case-control study will be conducted in the University Hospitals Leuven. This will be the largest-yet study on the subject, involving more than 750 patients. This will allow the creation of a specific cohort of patients where the vascular aspects are thought to be particularly important (low-tension glaucoma). It will use the largest combination yet of vascular-related measuring techniques (dynamic contour tonometry, optic coherent tomography, colour Doppler imaging and retinal oximetry)
Ocular blood flow has been consistently demonstrated to be altered in glaucoma patients when compared to otherwise healthy individuals. Numerous Doppler studies have shown a decrease in flow velocities in the retrobulbar arteries in what appears to be related to the degree of the glaucomatous disease. The anatomic pathway of the several arteries into the eye is intricately complicate, with at least one of them (the central retina artery) penetrating the optic nerve before entering the eye and supplying the innermost structures of the globe. As the optic nerve is surrounded by a layer of cerebrospinal fluid (CSF) which is in continuity with the rest of the central nervous system, this central retinal artery has also to cross this CSF containing compartment. Because of the intrinsic pressure this CSF - corresponding to the intracranial pressure at the orbital level - the possibility exists that this pressure around the optic disc could affect the blood flow of the arteries that go through it. The investigators will try to detect if a correlation exists between the optic nerve sheath diameter and the blood flow in the retrobulbar vessels of glaucoma patients.
Retinal ischemia is thought to play an important role in the pathogenesis of glaucoma. Recent findings have confirmed that there is a direct correlation between the levels of venous oxygen saturation and the degree of the glaucomatous disease, presumably due to a decrease in retinal cell metabolism. However, glaucoma patients have been suggested to have a different pattern in retinal venous circulation. For instance, the observation of a visible pulsating central retinal vein is a phenomenon that can be seen in up to 98% of the healthy individuals but is identifiable in less than 50% of glaucoma patients. While the nature of these venous changes are not year clear, the lack of a visible pulsating flow could suggest an increased intraluminal venous pressure due to some obstruction from both ocular or extraocular structures. This undetermined increase in venous pulse pressure could then significantly decrease perfusion pressures and therefore further decrease oxygen supply to the retinal tissues. The investigators will therefore try to determine if there is a significant difference between the oxygen saturation of the retinal vessels in both glaucoma patients with and without a visible pulsating central vein
In the double-masked, randomized, multi-center, active-controlled parallel study, patients will be randomized to receive either a fixed dose combination of AR-12286 and travoprost, AR-12286, or travoprost. The hypothesis is that there is no difference between each treatment arm.
This study will investigate if micropulse laser trabeculoplasty (532nm) is as effecttive as or better than the conventional laser trabeculoplasty (532nm), it might be a new treatment strategy for glaucoma patients. It is done with a laser device that can also be used for many other ophthalmic applications, thus reducing the economic burden of treatment.
This study will assess angle width in Chinese patients with Open-angle Glaucoma and/or Ocular Hypertension.
The purpose of this research study is to determine the diurnal and nocturnal effects of Travoprost with SofZia (Travatan Z) on intraocular pressure and ocular perfusion pressure.
In participants with a diagnosis of open angle glaucoma (OAG) or ocular hypertension (OHT), the primary objective is to demonstrate that the mean IOP reduction after 3 months of treatment with BOL-303259-X once daily (QD) is non-inferior to timolol maleate 0.5% twice daily (BID). The secondary objective is to demonstrate the superiority of BOL-303259-X QD to timolol maleate 0.5% BID. This assessment will be performed if the non-inferiority of BOL-303259-X QD to timolol maleate 0.5% BID is determined. An open label safety phase will be conducted at the end of Visit 6 (3 months) where all participants will receive BOL-303259-X QD for an additional 3 months.
In participants with a diagnosis of open angle glaucoma (OAG) or ocular hypertension (OHT), the primary objective is to demonstrate that the mean IOP reduction after 3 months of treatment with BOL-303259-X once daily (QD) is non-inferior to timolol maleate 0.5% twice daily (BID). The secondary objective is to demonstrate the superiority of BOL-303259-X QD to timolol maleate 0.5% BID. This assessment will be performed if the non-inferiority of BOL-303259-X QD to timolol maleate 0.5% BID is determined. An open label safety phase will be conducted at the end of Visit 6 (3 months) where all participants will receive BOL-303259-X QD for an additional 9 months.